DE4431117A1 - Circuit for receiving a light signal containing alternating light - Google Patents

Abstract

A circuit is used to set the operating point of at least one opto-electronic component, e.g. a photodiode (10'), in which the opto-electronic component is part of a receiver for useful alternating light signals. In order to set the operating point below the saturation voltage of the opto-electronic component, a resistance circuit is connected in parallel with the opto-electronic component at least to compensate for direct light signals. The resistance circuit has a self-adjusting resistor, the resistance variation of which is at least voltage-dependent as soon as a given voltage below the saturation voltage is exceeded and thus loads the opto-electronic component until the set voltage is substantially attained. The compensation current required owing to the direct light is produced without an outside voltage in such a way that virtually no current need be taken from the power supply.

Description

The invention relates to a circuit for receiving a change light signals containing sellicht according to the generic term of the An saying 1.

Such circuits are widely used to make changes in Measure the incidence of light and obtain usable signals from it. Because basically between the illuminance and the idle voltage with a photodiode be a logarithmic relationship stands, there is a quick reach with increasing lighting saturation voltage, which, depending on the photodiode used, is approx. 0.5 V is reached. Above this saturation voltage there is a linear relationship between illuminance and photocurrent across many powers of ten. If you want to include alternating lights converting light signals into a signal voltage, it is required The photodiode in a region below this saturation operating voltage in order to detect a waveform at all to be able to. For this purpose, it is known to use the photodiode in the To operate diode operation with bias. This is a preload voltage to the diode to block it (opposite polarity to saturation voltage). Alternatively, the diode can also be used in the element operation without bias. The photodiode works here as a power source. For this purpose, the photodiode is at a zero potential held while the photocurrent compensated through a resistor becomes.  

Both modes of operation, i.e. diode or element operation, have ge together that they need an external power source to the Be to compensate for any light current that occurs. Depending on the type of diode and lighting, this compensation current can range from a few tens of µA be a few mA. This current must come from the supply voltage are removed, which results in a particularly in battery operation rapid battery failure. Under certain circumstances, this Current to be drawn from the battery is a multiple of the current that the entire circuit takes up.

The circuit is preferably connected to a battery drive-powered water sensor used, as it from DE-U 93 09 837.5 is known. A battery powered use of water sensors is e.g. B. desirable in the field of boat building. Boats from "Leisure captains" usually have one or more sleeps place in the bow below the side sliding window. Now often ver eaten to close them so that water splashes the sleeping places drenched without the operator noticing. Will usually be here Check the window surfaces for splashes at moderate intervals water made by the known water sensor, these can if necessary, be closed automatically. Another area of application would be z. B. attachable to the clothesline of a housewife Water sensor that emits a signal when raindrops appear. Here, too, it is necessary to review the Appearance of water drops takes place. Such devices are so independent of an external power supply however, if it is operated with a 9 V block, the Average power consumption can be kept low.

Based on this prior art, the present Er The invention is therefore based on the task of regulating a photodiode Stromes to design so that almost no electricity from the Stromver supply or battery must be removed.

This object is solved by the features of claim 1.  

In the case of the photodiodes, the photodiode voltage loga also increases here rithmic with the illuminance until at 0.5 V the saturation voltage is reached. Leads in the range of the saturation voltage a further increase in illuminance to no further Voltage rise, d. H. a small alternating light component (LED module lation) does not affect the output voltage. Only in the Be AC voltage can develop in the area of the curve the. For this reason, the voltage on the photodiode must be on a Value below the saturation voltage. The easiest Most of the time this happens through a load resistor that has so much current consumes that the voltage across the photodiode z. B. always half the saturation voltage. No external electricity is used necessary, however, the resistance must always be the light intensity be fit. At z. B. U / 2 of the saturation voltage becomes a change light component always causes a voltage change across the resistor can call.

Further advantages result from the subclaims.

In the following the invention is based on several exemplary embodiments explained in more detail with reference to the drawings. Show it:

Fig. 1 shows a circuit in which a photodiode is a Ger maniumdiode tet geschal parallel with load resistor,

Fig. 2 is a circuit in which two photodiodes a Schottky or a silicon diode with a load resistance is connected in parallel,

Fig. 3 is a circuit in which a photodiode is connected in parallel with a field effect transistor,

Fig. 4 shows a circuit according to Fig. 2 with a symmetrical Ope rationsverstärker,

Fig. 5 is a circuit according to Fig. 1 with a SYMMETRI rule operational amplifier,

Fig. 6 shows a circuit according to Fig. 2 with a asymmetri rule amplifier circuit,

Fig. 7 is a circuit in which a photodiode, a transformer is connected in parallel,

Fig. 8 shows a circuit in which a controllable field-effect transistor is switched between two photodiodes, which is via an operational amplifier.

In Fig. 1, the photodiode 10 is exposed to an illumination L. A diode, here a germanium diode, is arranged parallel to the photodiode. With this germanium diode connected in series is a small load resistance of about 10 kilohms. When the voltage of the photodiode increases, the germanium diode opens at about 0.3 V, so that the photodiode is only loaded when a photo voltage of 0.3 V occurs. In this case, the excess voltage can then be reduced via the resistor 12 , since the internal resistance of the germanium diode changes as a function of the photo voltage. The resistor is used to prevent signal asymmetries at high illuminance levels (rectifier effects). The disadvantage of this scarf device is that germanium diodes are rarely used, so that this results in a relatively expensive circuit.

In Fig. 2, two photodiodes 10 ', 10 ''deliver a positive and negative voltage of a maximum of 1 V together. A Schott ky diode 13 (e.g. BAT 83) with a forward voltage of 0.4 V limits the Photo voltage to 0.2 V per photodiode. The same result can also be achieved by using a silicon diode (1N 41/48) with a forward voltage of approximately 0.6 V. The double output voltage is advantageous, disadvantageous the use of two photodiodes. As in the embodiment of FIG. 1, the Schottky diode 13 opens when the forward voltage is reached, so that the resistor 14 of z. B. 2 kiloohms can reduce the unnecessary photo voltage. In the exemplary embodiments in FIGS. 1, 2, however, the resistors 12 , 14 can also be dispensed with, provided the internal resistance of the diode 11 or the Schottky diode 13 is sufficient.

In the exemplary embodiment in FIG. 3, the lighting unit L subject to photodiode 10 is connected in parallel with a field-effect transistor 15 . The photodiode voltage is constantly compared with a reference voltage via an operational amplifier 16 and readjusted by means of the field-effect transistor. The field-effect transistor works as a variable resistor. The advantages of this circuit be that only one photodiode is required and also a very precise control. However, it is disadvantageous that the operational amplifier requires current; however, since slow operational amplifiers are preferably used here, the operational amplifier only requires a current of approximately 1.2 μA.

The circuits of FIGS. 1-3 may also be operated with a symmetric operational amplifier. This is shown for the embodiment of FIG. 2 in FIG. 4 and for the embodiment of FIG. 1 in FIG. 5. The operational amplifier is switched as a symmetrical amplifier. This suppresses common mode interference. The operational amplifier 17 is connected via capacitors in parallel to the germanium diode 11 or the Schottky diode 13 and the associated resistors 12 , 14 . Fig. 6 shows a simplification of the aforementioned circuits in that an unbalanced amplifier 28 is used.

An optimal but somewhat expensive solution is shown in Fig. 8. To regulate the photodiode current, a field-effect transistor 18 is arranged in series between two same-polarized photodiodes 10 ', 10 ''. In parallel to the field-effect transistor, an operational amplifier 19 is arranged. Resistors 20 , 21 are arranged between the photodiodes and the operational amplifier, which are bridged via capacitors 22 , 23 . The resistors are only used to compensate the positive or negative photo voltage for Operationsver stronger, so that at z. B. 0.2 V positive photo voltage and 0.2 V negative photo voltage are always 0 plus 0 V on the operational amplifier. The operational amplifier 19 can thus regulate the photodiode current via the field-effect transistor. The capacitors 22 , 23 serve to bypass the AC voltage, so that an alternating light can lead to a signal and thus a regulation. The direct current component is coupled out via the capacitor 29 , while the regulation of the photodiode current takes place via the line 30 . An alternating voltage suppression is finally carried out by the components 31 and 32 .

Finally, in FIG. 7, a transformer 24 is connected in parallel to a photodiode 10 . The transformer 24 in turn is connected to an operational amplifier 25 in parallel, and in addition a resonance element connected in parallel with these components can be provided. The transformer has the known property of having a low resistance for direct current, while having a high resistance for alternating current. While an output voltage arises due to the low internal resistance for direct current of approximately 0 V, an alternating current caused by an alternating light leads to an alternating voltage at the output of the transformer 24 .

All circuits have in common that the photodiode is dynamically loaded without electricity being taken from the supply to a significant extent. Without lighting, the photodiode and, if available, the load diodes are high-ohmic. When illuminated, the photodiode as a generator and the load diodes are never der Ohmig, and always so that the internal resistance of the photodio is compensated for by an equal internal resistance of the load diodes. (Embodiments of FIGS. 1, 2, 4, 5.) Since an output signal is always guaranteed even with a large proportion of extraneous light.

In a practical application, it has been found that a normal circuit with full sunlight, a current of 260 µA, which compensates by a counter voltage or current must be settled. In any case, this compensation current is larger than possible with continuous battery operation. With the mentioned Ausfüh examples (where a downstream low-current operation onsamplifier the task of generating control voltage for the field Effect transistor takes over as well as the AC voltage amplification is used) with high sensitivity a Stromver need with discrete amplifier in C-Mos technology and germanium Diode of 10 µA for the complete water sensor on average can be achieved. If you calculate the high current in the probably rare Aiarmfall with a, a commercial 9 V block can more than Hold for 2 years.

Claims (10)

1. Circuit for the reception of an alternating light-containing light signal (L), in particular within a reflection path of a water sensor, by means of at least one photodiode ( 10 ; 10 '; 10 ''), with a resistance circuit the photodiode even with increasing lighting in an area below holds the saturation voltage of the photodiode, in which the alternating light on the photodiode causes an alternating voltage that can be used as a signal, characterized in that the resistance circuit is connected in parallel to the photodiode and has a self-regulating resistor which automatically detects the voltage and regulates it in the range below the saturation voltage . 2. Circuit according to claim 1, characterized in that a diode ( 11 ), preferably a germanium diode, is connected in parallel as a self-regulating resistor of at least one photodiode ( 10 ), the threshold voltage of the diode ( 11 ) being approximately half the saturation voltage of the photodiode ( 10 ). corresponds ( Fig. 1). 3. A circuit according to claim 1, characterized in that two photodiodes ( 10 ', 10 ''), a Schottky diode ( 13 ) or a silicon diode is connected in parallel, the threshold voltage of the Schottky diode or the silicon diode approximately corresponds to half the saturation voltage of the photodiodes ( FIG. 2). 4. A circuit according to claim 2 or 3, characterized in that the diode ( 11 ) or the Schottky diode ( 13 ) or the silicon diode is connected in series with a resistor ( 12 , 14 ). 5. A circuit according to claim 1, characterized in that a field-effect transistor ( 15 ) is connected in parallel as a self-regulating resistor of at least one photodiode ( 10 ), the resistance of which is regulated by an operational amplifier ( 16 ) ( Fig. 3). 6. Circuit according to one of claims 1-5, characterized in that the at least one photodiode ( 10 ; 10 '; 10 '') and the self-regulating resistor, a symmetrical operational amplifier ( 17 ) is connected in parallel ( Fig. 4, 5). 7. Circuit according to one of the preceding claims, characterized in that a field-effect transistor ( 18 ) is arranged in series between two same-polarized photodiodes ( 10 ', 10 '') for regulating the photodiode current, which via a parallel-connected operational amplifier ( 19 ) can be regulated, upstream of which resistors ( 20 , 21 ) are connected upstream to compensate the photo voltage ( FIG. 8). 8. A circuit according to claim 1, characterized in that at least one photodiode ( 10 ) as a self-regulating resistor, a transformer ( 24 ) is connected in parallel ( Fig. 7). 9. A circuit according to claim 8, characterized in that the transformer ( 24 ) is followed by an operational amplifier ( 25 ) symmetrically. 10. A circuit according to claim 9, characterized in that the transformer ( 24 ) and the operational amplifier ( 25 ) has a resonance element ( 26 ) connected in parallel.